//===- MCCodeView.h - Machine Code CodeView support -------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // Holds state from .cv_file and .cv_loc directives for later emission. // //===----------------------------------------------------------------------===// #include "llvm/MC/MCCodeView.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/StringExtras.h" #include "llvm/DebugInfo/CodeView/CodeView.h" #include "llvm/DebugInfo/CodeView/Line.h" #include "llvm/DebugInfo/CodeView/SymbolRecord.h" #include "llvm/MC/MCAssembler.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCObjectStreamer.h" #include "llvm/MC/MCValue.h" #include "llvm/Support/EndianStream.h" using namespace llvm; using namespace llvm::codeview; CodeViewContext::~CodeViewContext() { // If someone inserted strings into the string table but never actually // emitted them somewhere, clean up the fragment. if (!InsertedStrTabFragment && StrTabFragment) StrTabFragment->destroy(); } /// This is a valid number for use with .cv_loc if we've already seen a .cv_file /// for it. bool CodeViewContext::isValidFileNumber(unsigned FileNumber) const { unsigned Idx = FileNumber - 1; if (Idx < Files.size()) return Files[Idx].Assigned; return false; } bool CodeViewContext::addFile(MCStreamer &OS, unsigned FileNumber, StringRef Filename, ArrayRef ChecksumBytes, uint8_t ChecksumKind) { assert(FileNumber > 0); auto FilenameOffset = addToStringTable(Filename); Filename = FilenameOffset.first; unsigned Idx = FileNumber - 1; if (Idx >= Files.size()) Files.resize(Idx + 1); if (Filename.empty()) Filename = ""; if (Files[Idx].Assigned) return false; FilenameOffset = addToStringTable(Filename); Filename = FilenameOffset.first; unsigned Offset = FilenameOffset.second; auto ChecksumOffsetSymbol = OS.getContext().createTempSymbol("checksum_offset", false); Files[Idx].StringTableOffset = Offset; Files[Idx].ChecksumTableOffset = ChecksumOffsetSymbol; Files[Idx].Assigned = true; Files[Idx].Checksum = ChecksumBytes; Files[Idx].ChecksumKind = ChecksumKind; return true; } MCCVFunctionInfo *CodeViewContext::getCVFunctionInfo(unsigned FuncId) { if (FuncId >= Functions.size()) return nullptr; if (Functions[FuncId].isUnallocatedFunctionInfo()) return nullptr; return &Functions[FuncId]; } bool CodeViewContext::recordFunctionId(unsigned FuncId) { if (FuncId >= Functions.size()) Functions.resize(FuncId + 1); // Return false if this function info was already allocated. if (!Functions[FuncId].isUnallocatedFunctionInfo()) return false; // Mark this as an allocated normal function, and leave the rest alone. Functions[FuncId].ParentFuncIdPlusOne = MCCVFunctionInfo::FunctionSentinel; return true; } bool CodeViewContext::recordInlinedCallSiteId(unsigned FuncId, unsigned IAFunc, unsigned IAFile, unsigned IALine, unsigned IACol) { if (FuncId >= Functions.size()) Functions.resize(FuncId + 1); // Return false if this function info was already allocated. if (!Functions[FuncId].isUnallocatedFunctionInfo()) return false; MCCVFunctionInfo::LineInfo InlinedAt; InlinedAt.File = IAFile; InlinedAt.Line = IALine; InlinedAt.Col = IACol; // Mark this as an inlined call site and record call site line info. MCCVFunctionInfo *Info = &Functions[FuncId]; Info->ParentFuncIdPlusOne = IAFunc + 1; Info->InlinedAt = InlinedAt; // Walk up the call chain adding this function id to the InlinedAtMap of all // transitive callers until we hit a real function. while (Info->isInlinedCallSite()) { InlinedAt = Info->InlinedAt; Info = getCVFunctionInfo(Info->getParentFuncId()); Info->InlinedAtMap[FuncId] = InlinedAt; } return true; } void CodeViewContext::recordCVLoc(MCContext &Ctx, const MCSymbol *Label, unsigned FunctionId, unsigned FileNo, unsigned Line, unsigned Column, bool PrologueEnd, bool IsStmt) { addLineEntry(MCCVLoc{ Label, FunctionId, FileNo, Line, Column, PrologueEnd, IsStmt}); } MCDataFragment *CodeViewContext::getStringTableFragment() { if (!StrTabFragment) { StrTabFragment = MCCtx->allocFragment(); // Start a new string table out with a null byte. StrTabFragment->getContents().push_back('\0'); } return StrTabFragment; } std::pair CodeViewContext::addToStringTable(StringRef S) { SmallVectorImpl &Contents = getStringTableFragment()->getContents(); auto Insertion = StringTable.insert(std::make_pair(S, unsigned(Contents.size()))); // Return the string from the table, since it is stable. std::pair Ret = std::make_pair(Insertion.first->first(), Insertion.first->second); if (Insertion.second) { // The string map key is always null terminated. Contents.append(Ret.first.begin(), Ret.first.end() + 1); } return Ret; } unsigned CodeViewContext::getStringTableOffset(StringRef S) { // A string table offset of zero is always the empty string. if (S.empty()) return 0; auto I = StringTable.find(S); assert(I != StringTable.end()); return I->second; } void CodeViewContext::emitStringTable(MCObjectStreamer &OS) { MCContext &Ctx = OS.getContext(); MCSymbol *StringBegin = Ctx.createTempSymbol("strtab_begin", false), *StringEnd = Ctx.createTempSymbol("strtab_end", false); OS.emitInt32(uint32_t(DebugSubsectionKind::StringTable)); OS.emitAbsoluteSymbolDiff(StringEnd, StringBegin, 4); OS.emitLabel(StringBegin); // Put the string table data fragment here, if we haven't already put it // somewhere else. If somebody wants two string tables in their .s file, one // will just be empty. if (!InsertedStrTabFragment) { OS.insert(getStringTableFragment()); InsertedStrTabFragment = true; } OS.emitValueToAlignment(Align(4), 0); OS.emitLabel(StringEnd); } void CodeViewContext::emitFileChecksums(MCObjectStreamer &OS) { // Do nothing if there are no file checksums. Microsoft's linker rejects empty // CodeView substreams. if (Files.empty()) return; MCContext &Ctx = OS.getContext(); MCSymbol *FileBegin = Ctx.createTempSymbol("filechecksums_begin", false), *FileEnd = Ctx.createTempSymbol("filechecksums_end", false); OS.emitInt32(uint32_t(DebugSubsectionKind::FileChecksums)); OS.emitAbsoluteSymbolDiff(FileEnd, FileBegin, 4); OS.emitLabel(FileBegin); unsigned CurrentOffset = 0; // Emit an array of FileChecksum entries. We index into this table using the // user-provided file number. Each entry may be a variable number of bytes // determined by the checksum kind and size. for (auto File : Files) { OS.emitAssignment(File.ChecksumTableOffset, MCConstantExpr::create(CurrentOffset, Ctx)); CurrentOffset += 4; // String table offset. if (!File.ChecksumKind) { CurrentOffset += 4; // One byte each for checksum size and kind, then align to 4 bytes. } else { CurrentOffset += 2; // One byte each for checksum size and kind. CurrentOffset += File.Checksum.size(); CurrentOffset = alignTo(CurrentOffset, 4); } OS.emitInt32(File.StringTableOffset); if (!File.ChecksumKind) { // There is no checksum. Therefore zero the next two fields and align // back to 4 bytes. OS.emitInt32(0); continue; } OS.emitInt8(static_cast(File.Checksum.size())); OS.emitInt8(File.ChecksumKind); OS.emitBytes(toStringRef(File.Checksum)); OS.emitValueToAlignment(Align(4)); } OS.emitLabel(FileEnd); ChecksumOffsetsAssigned = true; } // Output checksum table offset of the given file number. It is possible that // not all files have been registered yet, and so the offset cannot be // calculated. In this case a symbol representing the offset is emitted, and // the value of this symbol will be fixed up at a later time. void CodeViewContext::emitFileChecksumOffset(MCObjectStreamer &OS, unsigned FileNo) { unsigned Idx = FileNo - 1; if (Idx >= Files.size()) Files.resize(Idx + 1); if (ChecksumOffsetsAssigned) { OS.emitSymbolValue(Files[Idx].ChecksumTableOffset, 4); return; } const MCSymbolRefExpr *SRE = MCSymbolRefExpr::create(Files[Idx].ChecksumTableOffset, OS.getContext()); OS.emitValueImpl(SRE, 4); } void CodeViewContext::addLineEntry(const MCCVLoc &LineEntry) { size_t Offset = MCCVLines.size(); auto I = MCCVLineStartStop.insert( {LineEntry.getFunctionId(), {Offset, Offset + 1}}); if (!I.second) I.first->second.second = Offset + 1; MCCVLines.push_back(LineEntry); } std::vector CodeViewContext::getFunctionLineEntries(unsigned FuncId) { std::vector FilteredLines; size_t LocBegin; size_t LocEnd; std::tie(LocBegin, LocEnd) = getLineExtentIncludingInlinees(FuncId); if (LocBegin >= LocEnd) { return FilteredLines; } MCCVFunctionInfo *SiteInfo = getCVFunctionInfo(FuncId); for (size_t Idx = LocBegin; Idx != LocEnd; ++Idx) { unsigned LocationFuncId = MCCVLines[Idx].getFunctionId(); if (LocationFuncId == FuncId) { // This was a .cv_loc directly for FuncId, so record it. FilteredLines.push_back(MCCVLines[Idx]); } else { // Check if the current location is inlined in this function. If it is, // synthesize a statement .cv_loc at the original inlined call site. auto I = SiteInfo->InlinedAtMap.find(LocationFuncId); if (I != SiteInfo->InlinedAtMap.end()) { MCCVFunctionInfo::LineInfo &IA = I->second; // Only add the location if it differs from the previous location. // Large inlined calls will have many .cv_loc entries and we only need // one line table entry in the parent function. if (FilteredLines.empty() || FilteredLines.back().getFileNum() != IA.File || FilteredLines.back().getLine() != IA.Line || FilteredLines.back().getColumn() != IA.Col) { FilteredLines.push_back(MCCVLoc(MCCVLines[Idx].getLabel(), FuncId, IA.File, IA.Line, IA.Col, false, false)); } } } } return FilteredLines; } std::pair CodeViewContext::getLineExtent(unsigned FuncId) { auto I = MCCVLineStartStop.find(FuncId); // Return an empty extent if there are no cv_locs for this function id. if (I == MCCVLineStartStop.end()) return {~0ULL, 0}; return I->second; } std::pair CodeViewContext::getLineExtentIncludingInlinees(unsigned FuncId) { size_t LocBegin; size_t LocEnd; std::tie(LocBegin, LocEnd) = getLineExtent(FuncId); // Include all child inline call sites in our extent. MCCVFunctionInfo *SiteInfo = getCVFunctionInfo(FuncId); if (SiteInfo) { for (auto &KV : SiteInfo->InlinedAtMap) { unsigned ChildId = KV.first; auto Extent = getLineExtent(ChildId); LocBegin = std::min(LocBegin, Extent.first); LocEnd = std::max(LocEnd, Extent.second); } } return {LocBegin, LocEnd}; } ArrayRef CodeViewContext::getLinesForExtent(size_t L, size_t R) { if (R <= L) return std::nullopt; if (L >= MCCVLines.size()) return std::nullopt; return ArrayRef(&MCCVLines[L], R - L); } void CodeViewContext::emitLineTableForFunction(MCObjectStreamer &OS, unsigned FuncId, const MCSymbol *FuncBegin, const MCSymbol *FuncEnd) { MCContext &Ctx = OS.getContext(); MCSymbol *LineBegin = Ctx.createTempSymbol("linetable_begin", false), *LineEnd = Ctx.createTempSymbol("linetable_end", false); OS.emitInt32(uint32_t(DebugSubsectionKind::Lines)); OS.emitAbsoluteSymbolDiff(LineEnd, LineBegin, 4); OS.emitLabel(LineBegin); OS.emitCOFFSecRel32(FuncBegin, /*Offset=*/0); OS.emitCOFFSectionIndex(FuncBegin); // Actual line info. std::vector Locs = getFunctionLineEntries(FuncId); bool HaveColumns = any_of(Locs, [](const MCCVLoc &LineEntry) { return LineEntry.getColumn() != 0; }); OS.emitInt16(HaveColumns ? int(LF_HaveColumns) : 0); OS.emitAbsoluteSymbolDiff(FuncEnd, FuncBegin, 4); for (auto I = Locs.begin(), E = Locs.end(); I != E;) { // Emit a file segment for the run of locations that share a file id. unsigned CurFileNum = I->getFileNum(); auto FileSegEnd = std::find_if(I, E, [CurFileNum](const MCCVLoc &Loc) { return Loc.getFileNum() != CurFileNum; }); unsigned EntryCount = FileSegEnd - I; OS.AddComment( "Segment for file '" + Twine(getStringTableFragment() ->getContents()[Files[CurFileNum - 1].StringTableOffset]) + "' begins"); OS.emitCVFileChecksumOffsetDirective(CurFileNum); OS.emitInt32(EntryCount); uint32_t SegmentSize = 12; SegmentSize += 8 * EntryCount; if (HaveColumns) SegmentSize += 4 * EntryCount; OS.emitInt32(SegmentSize); for (auto J = I; J != FileSegEnd; ++J) { OS.emitAbsoluteSymbolDiff(J->getLabel(), FuncBegin, 4); unsigned LineData = J->getLine(); if (J->isStmt()) LineData |= LineInfo::StatementFlag; OS.emitInt32(LineData); } if (HaveColumns) { for (auto J = I; J != FileSegEnd; ++J) { OS.emitInt16(J->getColumn()); OS.emitInt16(0); } } I = FileSegEnd; } OS.emitLabel(LineEnd); } static bool compressAnnotation(uint32_t Data, SmallVectorImpl &Buffer) { if (isUInt<7>(Data)) { Buffer.push_back(Data); return true; } if (isUInt<14>(Data)) { Buffer.push_back((Data >> 8) | 0x80); Buffer.push_back(Data & 0xff); return true; } if (isUInt<29>(Data)) { Buffer.push_back((Data >> 24) | 0xC0); Buffer.push_back((Data >> 16) & 0xff); Buffer.push_back((Data >> 8) & 0xff); Buffer.push_back(Data & 0xff); return true; } return false; } static bool compressAnnotation(BinaryAnnotationsOpCode Annotation, SmallVectorImpl &Buffer) { return compressAnnotation(static_cast(Annotation), Buffer); } static uint32_t encodeSignedNumber(uint32_t Data) { if (Data >> 31) return ((-Data) << 1) | 1; return Data << 1; } void CodeViewContext::emitInlineLineTableForFunction(MCObjectStreamer &OS, unsigned PrimaryFunctionId, unsigned SourceFileId, unsigned SourceLineNum, const MCSymbol *FnStartSym, const MCSymbol *FnEndSym) { // Create and insert a fragment into the current section that will be encoded // later. auto *F = MCCtx->allocFragment( PrimaryFunctionId, SourceFileId, SourceLineNum, FnStartSym, FnEndSym); OS.insert(F); } MCFragment *CodeViewContext::emitDefRange( MCObjectStreamer &OS, ArrayRef> Ranges, StringRef FixedSizePortion) { // Create and insert a fragment into the current section that will be encoded // later. auto *F = MCCtx->allocFragment(Ranges, FixedSizePortion); OS.insert(F); return F; } static unsigned computeLabelDiff(const MCAssembler &Asm, const MCSymbol *Begin, const MCSymbol *End) { MCContext &Ctx = Asm.getContext(); MCSymbolRefExpr::VariantKind Variant = MCSymbolRefExpr::VK_None; const MCExpr *BeginRef = MCSymbolRefExpr::create(Begin, Variant, Ctx), *EndRef = MCSymbolRefExpr::create(End, Variant, Ctx); const MCExpr *AddrDelta = MCBinaryExpr::create(MCBinaryExpr::Sub, EndRef, BeginRef, Ctx); int64_t Result; bool Success = AddrDelta->evaluateKnownAbsolute(Result, Asm); assert(Success && "failed to evaluate label difference as absolute"); (void)Success; assert(Result >= 0 && "negative label difference requested"); assert(Result < UINT_MAX && "label difference greater than 2GB"); return unsigned(Result); } void CodeViewContext::encodeInlineLineTable(const MCAssembler &Asm, MCCVInlineLineTableFragment &Frag) { size_t LocBegin; size_t LocEnd; std::tie(LocBegin, LocEnd) = getLineExtentIncludingInlinees(Frag.SiteFuncId); if (LocBegin >= LocEnd) return; ArrayRef Locs = getLinesForExtent(LocBegin, LocEnd); if (Locs.empty()) return; // Check that the locations are all in the same section. #ifndef NDEBUG const MCSection *FirstSec = &Locs.front().getLabel()->getSection(); for (const MCCVLoc &Loc : Locs) { if (&Loc.getLabel()->getSection() != FirstSec) { errs() << ".cv_loc " << Loc.getFunctionId() << ' ' << Loc.getFileNum() << ' ' << Loc.getLine() << ' ' << Loc.getColumn() << " is in the wrong section\n"; llvm_unreachable(".cv_loc crosses sections"); } } #endif // Make an artificial start location using the function start and the inlinee // lines start location information. All deltas start relative to this // location. MCCVLoc StartLoc = Locs.front(); StartLoc.setLabel(Frag.getFnStartSym()); StartLoc.setFileNum(Frag.StartFileId); StartLoc.setLine(Frag.StartLineNum); bool HaveOpenRange = false; const MCSymbol *LastLabel = Frag.getFnStartSym(); MCCVFunctionInfo::LineInfo LastSourceLoc, CurSourceLoc; LastSourceLoc.File = Frag.StartFileId; LastSourceLoc.Line = Frag.StartLineNum; MCCVFunctionInfo *SiteInfo = getCVFunctionInfo(Frag.SiteFuncId); SmallVectorImpl &Buffer = Frag.getContents(); Buffer.clear(); // Clear old contents if we went through relaxation. for (const MCCVLoc &Loc : Locs) { // Exit early if our line table would produce an oversized InlineSiteSym // record. Account for the ChangeCodeLength annotation emitted after the // loop ends. constexpr uint32_t InlineSiteSize = 12; constexpr uint32_t AnnotationSize = 8; size_t MaxBufferSize = MaxRecordLength - InlineSiteSize - AnnotationSize; if (Buffer.size() >= MaxBufferSize) break; if (Loc.getFunctionId() == Frag.SiteFuncId) { CurSourceLoc.File = Loc.getFileNum(); CurSourceLoc.Line = Loc.getLine(); } else { auto I = SiteInfo->InlinedAtMap.find(Loc.getFunctionId()); if (I != SiteInfo->InlinedAtMap.end()) { // This .cv_loc is from a child inline call site. Use the source // location of the inlined call site instead of the .cv_loc directive // source location. CurSourceLoc = I->second; } else { // We've hit a cv_loc not attributed to this inline call site. Use this // label to end the PC range. if (HaveOpenRange) { unsigned Length = computeLabelDiff(Asm, LastLabel, Loc.getLabel()); compressAnnotation(BinaryAnnotationsOpCode::ChangeCodeLength, Buffer); compressAnnotation(Length, Buffer); LastLabel = Loc.getLabel(); } HaveOpenRange = false; continue; } } // Skip this .cv_loc if we have an open range and this isn't a meaningful // source location update. The current table format does not support column // info, so we can skip updates for those. if (HaveOpenRange && CurSourceLoc.File == LastSourceLoc.File && CurSourceLoc.Line == LastSourceLoc.Line) continue; HaveOpenRange = true; if (CurSourceLoc.File != LastSourceLoc.File) { unsigned FileOffset = static_cast( Files[CurSourceLoc.File - 1] .ChecksumTableOffset->getVariableValue()) ->getValue(); compressAnnotation(BinaryAnnotationsOpCode::ChangeFile, Buffer); compressAnnotation(FileOffset, Buffer); } int LineDelta = CurSourceLoc.Line - LastSourceLoc.Line; unsigned EncodedLineDelta = encodeSignedNumber(LineDelta); unsigned CodeDelta = computeLabelDiff(Asm, LastLabel, Loc.getLabel()); if (EncodedLineDelta < 0x8 && CodeDelta <= 0xf) { // The ChangeCodeOffsetAndLineOffset combination opcode is used when the // encoded line delta uses 3 or fewer set bits and the code offset fits // in one nibble. unsigned Operand = (EncodedLineDelta << 4) | CodeDelta; compressAnnotation(BinaryAnnotationsOpCode::ChangeCodeOffsetAndLineOffset, Buffer); compressAnnotation(Operand, Buffer); } else { // Otherwise use the separate line and code deltas. if (LineDelta != 0) { compressAnnotation(BinaryAnnotationsOpCode::ChangeLineOffset, Buffer); compressAnnotation(EncodedLineDelta, Buffer); } compressAnnotation(BinaryAnnotationsOpCode::ChangeCodeOffset, Buffer); compressAnnotation(CodeDelta, Buffer); } LastLabel = Loc.getLabel(); LastSourceLoc = CurSourceLoc; } assert(HaveOpenRange); unsigned EndSymLength = computeLabelDiff(Asm, LastLabel, Frag.getFnEndSym()); unsigned LocAfterLength = ~0U; ArrayRef LocAfter = getLinesForExtent(LocEnd, LocEnd + 1); if (!LocAfter.empty()) { // Only try to compute this difference if we're in the same section. const MCCVLoc &Loc = LocAfter[0]; if (&Loc.getLabel()->getSection() == &LastLabel->getSection()) LocAfterLength = computeLabelDiff(Asm, LastLabel, Loc.getLabel()); } compressAnnotation(BinaryAnnotationsOpCode::ChangeCodeLength, Buffer); compressAnnotation(std::min(EndSymLength, LocAfterLength), Buffer); } void CodeViewContext::encodeDefRange(const MCAssembler &Asm, MCCVDefRangeFragment &Frag) { MCContext &Ctx = Asm.getContext(); SmallVectorImpl &Contents = Frag.getContents(); Contents.clear(); SmallVectorImpl &Fixups = Frag.getFixups(); Fixups.clear(); raw_svector_ostream OS(Contents); // Compute all the sizes up front. SmallVector, 4> GapAndRangeSizes; const MCSymbol *LastLabel = nullptr; for (std::pair Range : Frag.getRanges()) { unsigned GapSize = LastLabel ? computeLabelDiff(Asm, LastLabel, Range.first) : 0; unsigned RangeSize = computeLabelDiff(Asm, Range.first, Range.second); GapAndRangeSizes.push_back({GapSize, RangeSize}); LastLabel = Range.second; } // Write down each range where the variable is defined. for (size_t I = 0, E = Frag.getRanges().size(); I != E;) { // If the range size of multiple consecutive ranges is under the max, // combine the ranges and emit some gaps. const MCSymbol *RangeBegin = Frag.getRanges()[I].first; unsigned RangeSize = GapAndRangeSizes[I].second; size_t J = I + 1; for (; J != E; ++J) { unsigned GapAndRangeSize = GapAndRangeSizes[J].first + GapAndRangeSizes[J].second; if (RangeSize + GapAndRangeSize > MaxDefRange) break; RangeSize += GapAndRangeSize; } unsigned NumGaps = J - I - 1; support::endian::Writer LEWriter(OS, llvm::endianness::little); unsigned Bias = 0; // We must split the range into chunks of MaxDefRange, this is a fundamental // limitation of the file format. do { uint16_t Chunk = std::min((uint32_t)MaxDefRange, RangeSize); const MCSymbolRefExpr *SRE = MCSymbolRefExpr::create(RangeBegin, Ctx); const MCBinaryExpr *BE = MCBinaryExpr::createAdd(SRE, MCConstantExpr::create(Bias, Ctx), Ctx); // Each record begins with a 2-byte number indicating how large the record // is. StringRef FixedSizePortion = Frag.getFixedSizePortion(); // Our record is a fixed sized prefix and a LocalVariableAddrRange that we // are artificially constructing. size_t RecordSize = FixedSizePortion.size() + sizeof(LocalVariableAddrRange) + 4 * NumGaps; // Write out the record size. LEWriter.write(RecordSize); // Write out the fixed size prefix. OS << FixedSizePortion; // Make space for a fixup that will eventually have a section relative // relocation pointing at the offset where the variable becomes live. Fixups.push_back(MCFixup::create(Contents.size(), BE, FK_SecRel_4)); LEWriter.write(0); // Fixup for code start. // Make space for a fixup that will record the section index for the code. Fixups.push_back(MCFixup::create(Contents.size(), BE, FK_SecRel_2)); LEWriter.write(0); // Fixup for section index. // Write down the range's extent. LEWriter.write(Chunk); // Move on to the next range. Bias += Chunk; RangeSize -= Chunk; } while (RangeSize > 0); // Emit the gaps afterwards. assert((NumGaps == 0 || Bias <= MaxDefRange) && "large ranges should not have gaps"); unsigned GapStartOffset = GapAndRangeSizes[I].second; for (++I; I != J; ++I) { unsigned GapSize, RangeSize; assert(I < GapAndRangeSizes.size()); std::tie(GapSize, RangeSize) = GapAndRangeSizes[I]; LEWriter.write(GapStartOffset); LEWriter.write(GapSize); GapStartOffset += GapSize + RangeSize; } } }